Difference between revisions of "Free associative algebra"
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The algebra $k\langle X \rangle$ of polynomials over a field $k$ in non-commuting variables in $X$. The following universal property determines the algebra $k\langle X \rangle$ uniquely up to an isomorphism: There is a mapping $i : k \rightarrow k\langle X \rangle$ such that any mapping from $X$ into an associative algebra $A$ with a unit over $k$ can be factored through $k\langle X \rangle$ in a unique way. The basic properties of $k\langle X \rangle$ are: | The algebra $k\langle X \rangle$ of polynomials over a field $k$ in non-commuting variables in $X$. The following universal property determines the algebra $k\langle X \rangle$ uniquely up to an isomorphism: There is a mapping $i : k \rightarrow k\langle X \rangle$ such that any mapping from $X$ into an associative algebra $A$ with a unit over $k$ can be factored through $k\langle X \rangle$ in a unique way. The basic properties of $k\langle X \rangle$ are: | ||
− | 1) $k\langle X \rangle$ can be imbedded in a skew-field (the Mal'tsev–Neumann theorem); | + | 1) $k\langle X \rangle$ can be imbedded in a [[skew-field]] (the Mal'tsev–Neumann theorem); |
2) $k\langle X \rangle$ has a weak division algorithm, that is, the relation | 2) $k\langle X \rangle$ has a weak division algorithm, that is, the relation | ||
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(here $d(a)$ is the usual degree of a polynomial $a \in k\langle X \rangle$, $d(0) = -\infty$); | (here $d(a)$ is the usual degree of a polynomial $a \in k\langle X \rangle$, $d(0) = -\infty$); | ||
− | 3) $k\langle X \rangle$ is a left (respectively, right) free ideal ring (that is, any left (respectively, right) ideal of $k\langle X \rangle$ is a free module of uniquely determined rank); | + | 3) $k\langle X \rangle$ is a left (respectively, right) [[free ideal ring]] (that is, any left (respectively, right) ideal of $k\langle X \rangle$ is a free module of uniquely determined rank); |
4) the centralizer of any non-scalar element of $k\langle X \rangle$ (that is, the set of elements that commute with a given element) is isomorphic to the algebra of polynomials over $k$ in a single variable (Bergman's theorem). | 4) the centralizer of any non-scalar element of $k\langle X \rangle$ (that is, the set of elements that commute with a given element) is isomorphic to the algebra of polynomials over $k$ in a single variable (Bergman's theorem). |
Revision as of 17:32, 16 October 2014
The algebra $k\langle X \rangle$ of polynomials over a field $k$ in non-commuting variables in $X$. The following universal property determines the algebra $k\langle X \rangle$ uniquely up to an isomorphism: There is a mapping $i : k \rightarrow k\langle X \rangle$ such that any mapping from $X$ into an associative algebra $A$ with a unit over $k$ can be factored through $k\langle X \rangle$ in a unique way. The basic properties of $k\langle X \rangle$ are:
1) $k\langle X \rangle$ can be imbedded in a skew-field (the Mal'tsev–Neumann theorem);
2) $k\langle X \rangle$ has a weak division algorithm, that is, the relation $$ d \left({ \sum_{i=1}^n a_i b_i }\right) < \max_i \{ d(a_i) + d(b_i) \} $$ where $a_i, b_i \in k\langle X \rangle$, all the $a_i$ are non-zero ($i = 1,\ldots,n$), $d(a_1) \le \cdots \le d(a_n)$, always implies that there are an integer $r$, $1 < r \le n$, and elements $c_,\ldots,c_{r-1}$ such that $$ d\left({ a_r - \sum_{i=1}^{r-1} a_i c_i }\right) < d(a_r) $$ and $$ d(a_i) + d(c_i) < d(a_r),\ \ \ i=1,\ldots,r-1 $$ (here $d(a)$ is the usual degree of a polynomial $a \in k\langle X \rangle$, $d(0) = -\infty$);
3) $k\langle X \rangle$ is a left (respectively, right) free ideal ring (that is, any left (respectively, right) ideal of $k\langle X \rangle$ is a free module of uniquely determined rank);
4) the centralizer of any non-scalar element of $k\langle X \rangle$ (that is, the set of elements that commute with a given element) is isomorphic to the algebra of polynomials over $k$ in a single variable (Bergman's theorem).
References
[1] | P.M. Cohn, "Universal algebra" , Reidel (1981) |
[2] | P.M. Cohn, "Free rings and their relations" , Acad. Press (1971) |
Free associative algebra. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Free_associative_algebra&oldid=33686